Paolo Masala scite author profile

In this paper, we present a comprehensive study on low hydration Ir/IrO 2 electrodes, made of an Ir core and an IrO 2 shell, that are designed and synthesized with an innovative, green approach, in order to have a higher surface/bulk ratio of Ir−O active centers. Three materials with different hydration degrees have been deeply investigated in terms of structure and microstructure by means of transmission electron microscopy (TEM) and synchrotron radiation techniques such as high-resolution (HR) and pair distribution function (PDF) quality Xray powder diffraction (XRPD), X-ray absorption spectroscopy (XAS), and for what concerns their electrochemical properties by means of cyclic voltammetry and steady-state I/E curves. The activity of these materials is compared and discussed in the light of our most recent results on hydrous IrO x . The main conclusion of this study is that the Ir core is noninteracting with the IrO x shell, the latter being able to easily accommodate Ir in different oxidation states, as previously suggested for the hydrated form, thus explaining the activity as electrocatalysts. In addition, in operando XAS experiments assessed that the catalytic cycle involves Ir(III) and (V), as previously established for the highly hydrated IrO x material.

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Rare Earth doped ceria: a combined X-ray and neutron pair distribution function study

Coduri

Brunelli²,

Scavini

et al. 2012

Zeitschrift für Kristallographie

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RareEarth doped ceria materials (Ce 1Àx RE x O 2Àx/2 ) are widely studied for their application in solid oxide fuel cell devices. In this work, RE(Yb, Y, Nd, La)-doped ceria samples at constant (x ¼ 0.25) doping rate were subjected to a combined synchrotron radiation and neutron powder diffraction study. The dopants were chosen in order to cover a wide range of dopant-ionic radii. The effect of doping on the average structure is investigated using conventional Rietveld analysis, while the Pair Distribution Function technique is used to explore the spatial extent of disorder as well as the local structure. Two models for mapping the local structure, in terms of oxygen relaxation and nano-phase separation, are presented.

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Phase Transformations in the CeO₂–Sm₂O₃ System: A Multiscale Powder Diffraction Investigation

et al. 2017

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The structure evolution in the CeO-SmO system is revisited by combining high resolution synchrotron powder diffraction with pair distribution function (PDF) to inquire about local, mesoscopic, and average structure. The CeO fluorite structure undergoes two phase transformations by Sm doping, first to a cubic (C-type) and then to a monoclinic (B-type) phase. Whereas the C to B-phase separation occurs completely and on a long-range scale, no miscibility gap is detected between fluorite and C-type phases. The transformation rather occurs by growth of C-type nanodomains embedded in the fluorite matrix, without any long-range phase separation. A side effect of this mechanism is the ordering of the oxygen vacancies, which is detrimental for the application of doped ceria as an electrolyte in fuel cells. The results are discussed in the framework of other Y and Gd dopants, and the relationship between nanostructuring and the above equilibria is also investigated.

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Percolating hierarchical defect structures drive phase transformation in Ce_1−xGd_xO_2−x/2: a total scattering study

Scavini

Coduri

Allieta

et al. 2015

IUCrJ

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Pair distribution function analysis up to tens of nanometres allows probing of the structural changes in Ce1−xGdxO2−x/2 solid solutions at varying gadolinium concentrations. Dopant ions and oxygen vacancies form extended Gd2O3-like clusters (droplets) and nanodomains which, on increasing the Gd concentration, percolate and cause a long-range phase transformation. A general crystallographic rationale is presented which could be adopted to describe phase transformations in highly doped materials.

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In situ pair distribution function study on lanthanum doped ceria

Coduri¹,

Scavini²,

Brunelli³

et al. 2013

Phys. Chem. Chem. Phys.

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Doped ceria materials are widely studied for their application in solid oxide fuel cell devices. In this work we report on the average and local structure evolution of La-doped ceria (Ce(1-x)La(x)O(2-x/2), x = 0.25) under fuel cells' operating conditions. The effect of doping on the average structure is investigated using conventional Rietveld analysis of neutron powder diffraction data. The extent of disorder as well as the local structure evolution at high temperature are investigated by employing very hard X-rays under both air and reducing atmosphere.

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Paolo Masala

Easy Accommodation of Different Oxidation States in Iridium Oxide Nanoparticles with Different Hydration Degree as Water Oxidation Electrocatalysts

Rare Earth doped ceria: a combined X-ray and neutron pair distribution function study

Phase Transformations in the CeO₂–Sm₂O₃ System: A Multiscale Powder Diffraction Investigation

Percolating hierarchical defect structures drive phase transformation in Ce_1−xGd_xO_2−x/2: a total scattering study

In situ pair distribution function study on lanthanum doped ceria

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Paolo Masala

Easy Accommodation of Different Oxidation States in Iridium Oxide Nanoparticles with Different Hydration Degree as Water Oxidation Electrocatalysts

Rare Earth doped ceria: a combined X-ray and neutron pair distribution function study

Phase Transformations in the CeO2–Sm2O3 System: A Multiscale Powder Diffraction Investigation

Percolating hierarchical defect structures drive phase transformation in Ce1−xGdxO2−x/2: a total scattering study

In situ pair distribution function study on lanthanum doped ceria

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Product

Resources

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Phase Transformations in the CeO₂–Sm₂O₃ System: A Multiscale Powder Diffraction Investigation

Percolating hierarchical defect structures drive phase transformation in Ce_1−xGd_xO_2−x/2: a total scattering study